KR102129051B1 - Mobile communication relay having exchangeable communication module - Google Patents

Abstract

The present invention relates to a mobile communication repeater including a replaceable communication module. The mobile communication repeater according to the present invention is accommodated so as to be detachably attached to the case, the case, and is connected to the link antenna, separating the first frequency downlink signal and the second frequency downlink signal from the downlink signal input from the link antenna, and the first A first frequency module, case for outputting a first noise-removing downlink signal from which noise of the frequency downlink signal is removed, outputting a first amplification downlink signal amplifying the first digital processing downlink signal, and outputting a second frequency downlink signal. It is accommodated so as to be detachable, connected to the service antenna, and outputs a second noise removal down signal which removes noise of the second frequency down signal, and a second amplification down signal which power-amplifies the second digital processing down signal. Output, and a second frequency module for outputting the first amplified downlink signal to a service antenna, and a first noise canceling downlink signal received from the first frequency module that is accommodated and detachably attached to the case. Outputs the converted first digital processing downlink signal to the first frequency module, digitally converts the second noise reduction downlink signal input from the second frequency module, digital processing, and converts the second digital processing downlink analog signal to the second frequency. It includes a digital processing module output to the module.

Description

Mobile communication repeater including replaceable communication module {MOBILE COMMUNICATION RELAY HAVING EXCHANGEABLE COMMUNICATION MODULE}

The present invention relates to a mobile communication repeater, and more particularly, to a mobile communication repeater including a replaceable communication module.

With the development of communication technology, the penetration rate of mobile communication terminals increases, and as users' needs and demands for call quality increase, mobile communication repeaters are spreading to solve this. A mobile communication repeater is a device that connects a base station and a terminal in the middle. Incidentally, although the base station receives radio waves from a mobile operator exchange to enable service, a mobile communication repeater is used to transmit radio waves of the base station more accurately and farther, since the radio wave arrival distance from the base station is limited. Mobile communication repeaters are often installed in small towns or mountainous areas far from base stations rather than large cities.

Various types of mobile communication repeaters are disclosed for each use, and there are optical repeaters and RF repeaters as representative mobile communication repeaters. The optical repeater has a method of transmitting to an area where radio wave facilities such as buildings and subways are fully equipped and where radio waves are unstable or call quality is poor. RF repeater is a radio communication equipment for radio wave shadow area cancellation in underground or ground space where it is difficult to transmit signals such as LTE, WCDMA, and CDMA, and provides signal amplification and radio path between base stations and terminals so that calls can be made smoothly. It is used for the purpose.

The mobile communication repeater has a case and various internal parts for relaying the communication therein. Depending on the situation, the mobile communication repeater may require internal components. A typical case is that the frequency band and/or bandwidth is changed according to the development of mobile communication technology. In this case, the conventional mobile communication repeater causes a problem in that the management efficiency of the mobile communication network is deteriorated because the entire repeater must be replaced or all components for signal processing must be replaced. In addition, considering that the mobile communication repeater is installed and used in a place where the user cannot access, it is difficult to remove the internal parts as in the related art.

The present invention is to provide a mobile communication repeater that can improve the efficiency of mobile communication network management through a replaceable communication module and facilitate the replacement of internal parts.

According to an embodiment of the present invention, the case; It is accommodated so as to be detachably attached to the case, is connected to the link antenna, separates the first frequency downlink signal and the second frequency downlink signal from the downlink signal input from the link antenna, and removes the noise of the first frequency downlink signal. A first frequency module for outputting a first noise canceling downlink signal, outputting a first amplification downlink signal amplifying the first digital processing downlink signal, and outputting the second frequency downlink signal; A second amplified downlink signal that is accommodated so as to be detachably attached to the case, is connected to a service antenna, outputs a second noise downlink signal from which noise of the second frequency downlink signal is removed, and amplifies the second digital processing downlink signal. A second frequency module outputting the signal to the service antenna and outputting the first amplified downlink signal to the service antenna; And the first digital processing downstream signal, which is accommodated so as to be detachably attached to the case, and digitally converts, digitally processes, and analogly converts the first noise reduction downstream signal input from the first frequency module to the first frequency module. And a digital processing module for digitally converting, digitally and analogly converting the second noise canceling down signal input from the second frequency module to the second frequency module. A mobile communication repeater is disclosed.

According to an embodiment, the first frequency module is connected to the link antenna, separating the first frequency downlink signal and the second frequency downlink signal from the downlink signal, and the second frequency downlink signal to the first 2, a first duplexing unit output to the frequency module.

According to an embodiment, the second frequency module may include a second link interface unit connected to the first redundancy unit and receiving the second frequency downlink signal.

According to an embodiment, the second frequency module is connected to the service antenna, and is connected to the first frequency module, and outputting the first amplified downlink signal input from the first frequency module to the service antenna. 2 redundancy; may include.

According to an embodiment, the first frequency module may include a first service interface unit connected to the second redundancy unit and outputting the first amplified downlink signal.

According to an embodiment, the second frequency module separates a first frequency up signal and a second frequency up signal from an uplink signal input from the service antenna, and removes noise of the second frequency up signal. Outputs a cancellation up signal, outputs a second amplified up signal that amplifies the second digital processing up signal to the first frequency module, outputs the first frequency up signal to the first frequency module, and outputs the second up signal. The first frequency module outputs a first noise canceling up signal from which the noise of the first frequency up signal is removed, and outputs a first amplified up signal that amplifies the first digital processing up signal to the link antenna, 2 The amplification enhancement signal is output to the link antenna, and the digital processing module converts the first noise removal enhancement signal input from the first frequency module into digital conversion, digital processing, and analog conversion. To the first frequency module, and digitally converting, digitally and analogly converting the second noise canceling up signal input from the second frequency module to the second frequency module. can do.

According to an embodiment, the second frequency module is connected to the service antenna, separating the first frequency up signal and the second frequency up signal from the uplink signal, and the first frequency up signal It may include a; a second redundancy unit output to the frequency module.

According to an embodiment, the first frequency module may include a first service interface unit connected to the second redundancy unit and receiving the first frequency enhancement signal.

According to an embodiment, the first frequency module is connected to the link antenna, and is connected to the second frequency module, and outputting the second amplified uplink signal input from the second frequency module to the link antenna. 1 can be included;

The second frequency module may include a second link interface unit connected to the first redundancy unit and outputting the second amplified uplink signal.

According to an embodiment, the first duplexer may include a diplexer separating the first frequency downlink signal and the second frequency downlink signal from the downlink signal.

According to an embodiment, the second duplexer may include a diplexer separating the first frequency uplink signal and the second frequency uplink signal from the uplink signal.

According to another embodiment of the invention, the case; It is accommodated detachably in the case, is connected to the link antenna, separates a first frequency downlink signal and a first other frequency downlink signal from a downlink signal input from the link antenna, and reduces the noise of the first frequency downlink signal. A first frequency module for outputting the removed first noise-removing downlink signal, outputting a first amplification downlink signal amplifying the first digital processing downlink signal, and outputting the first other frequency downlink signal; It is accommodated so as to be detachably attached to the case, and separates the n-1 frequency down signal and the n-1 other frequency down signal included in the first other frequency down signal, and reduces the noise of the n-1 frequency down signal. An n-th outputting the removed n-1 noise downlink signal, outputting an n-1 amplified downlink signal amplifying the n-1 digital processing downlink signal, and outputting the n-1 other frequency downlink signal -1 frequency module-provided that n is a natural number of 3 or more; It is accommodated so as to be detachably attached to the case, is connected to a service antenna, and outputs an n-th noise rejection down signal that removes noise of the n-th frequency down signal included in the n-1 other frequency down signal, and performs nth digital processing. An n-th frequency module for outputting an n-amplification downlink signal amplifying a downlink signal to the service antenna, and outputting the first amplification downlink signal and the n-1 amplification downlink signal to the service antenna; And the first digital processing downstream signal, which is accommodated so as to be detachably attached to the case, and digitally converts, digitally processes, and analogly converts the first noise reduction downstream signal input from the first frequency module to the first frequency module. And digitally converting, digitally processing, and analog-converting the n-1 noise canceling down signal input from the n-1 frequency module to the n-1 frequency module. And a digital processing module for digitally converting, digitally processing, and analog-converting the n-th noise removing downlink signal input from the n-th frequency module to the n-th frequency module. A mobile communication repeater is disclosed.

According to an embodiment, the mobile communication repeater is accommodated to be detachably attached to the case, and separates the n-2 frequency down signal and the n-2 other frequency down signal included in the first other frequency down signal, and the Output the n-2 noise cancellation down signal from which the noise of the n-2 frequency down signal is removed, and output the n-2 amplification down signal from the n-2 digital processing down signal to the n-th frequency module. And an n-2 frequency module outputting the n-2 other frequency downlink signal to the n-1 frequency module-provided that n is a natural number of 4 or more; The n-2 digital processing downstream signal, which is digitally converted, digitally processed, and analog-converted the n-2 noise reduction downstream signal input from the n-2 frequency module, is output to the n-2 frequency module, and the The n-1 frequency module divides the n-2 second frequency down signal into the n-1 frequency down signal and the n-1 other frequency down signal, and the nth frequency module is the n-2 frequency down signal. The amplified downlink signal may be output to the service antenna.

According to an embodiment, the nth frequency module separates an nth upstream frequency signal from an nth other upstream frequency signal from an uplink signal input from the service antenna, and removes noise from the nth upstream frequency signal. Outputs the noise canceling up signal, outputs the nth amplification up signal that amplifies the nth digital processing up signal to the first frequency module, and outputs the nth other frequency up signal to the n-1 frequency module The n-1 frequency module separates the n-1 frequency up signal and the n-1 other frequency up signal from the n n other frequency up signal, and reduces the noise of the n-1 frequency up signal. Outputs the removed n-1 noise canceling enhancement signal, outputs an n-1 amplification enhancement signal obtained by power-amplifying the n-1 digital processing enhancement signal to the first frequency module, and increases the n-1 other frequency. Outputs a signal, and the first frequency module outputs a first noise removal enhancement signal from which noise of a first frequency enhancement included in the n-1 frequency enhancement signal is removed, and amplifies the first digital processing enhancement signal. The first amplified boost signal is output to the link antenna, the n amplified boost signal and the n-1 amplified boost signal are output to the link antenna, and the digital processing module is input from the first frequency module. The first digital processing enhanced signal, which is digitally converted, digitally processed and analog-converted the first noise canceling enhanced signal, is output to the first frequency module, and the n-1 input from the n-1 frequency module. The n-1 digital processing enhancement signal obtained by digitally converting, digitally and analogly converting a noise canceling signal is output to the n-1 frequency module, and the nth noise removal enhancement signal is input from the nth frequency module. The digital conversion, digital processing, and analog conversion of the n-th digital processing enhancement signal may be output to the n-th frequency module.

According to the present invention, it is possible to provide a mobile communication repeater capable of enhancing the efficiency of mobile communication network management through the replaceable communication module and facilitating the replacement of internal parts.

Brief descriptions of each drawing are provided in order to better understand the drawings cited herein.
1 is a diagram schematically showing some components of a mobile communication system according to an embodiment of the present invention.
2 is a block diagram of the configuration of a mobile communication repeater according to an embodiment of the present invention.
FIG. 3 is a block diagram of a logical function of a mobile communication repeater when two frequency modules are included.
4 is a block diagram of a first duplexer according to an embodiment of the present invention.
5 is a block diagram of a logical function of a mobile communication repeater for a case where n frequency modules are included.

The technical idea of the present invention can be applied to various changes and can have various embodiments, and specific embodiments will be illustrated in the drawings and described in detail through detailed description. However, this is not intended to limit the technical spirit of the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the scope of the technical spirit of the present invention.

In describing the technical spirit of the present invention, when it is determined that a detailed description of related known technologies may unnecessarily obscure the subject matter of the technical spirit of the present invention, the detailed description is omitted. In addition, the numbers (for example, first, second, etc.) used in the description process of the present specification are only identification symbols for distinguishing one component from other components.

In addition, in this specification, when one component is referred to as "connected" or "connected" with another component, the one component may be directly connected to the other component, or may be directly connected, but in particular It should be understood that, as long as there is no objection to the contrary, it may or may be connected via another component in the middle.

In addition, terms such as “~ unit”, “~ group”, “~ character”, “~ module”, and “~ unit” described in the present specification mean a unit that processes at least one function or operation, which is a processor. (Processor), Microprocessor (Micro Processer), Microcontroller (Micro Controller), CPU (Central Processing Unit), GPU (Graphics Processing Unit), APU (Accelerate Processor Unit), DSP (Digital Signal Processor), ASIC (Application Specific) Integrated Circuit (FP), Field Programmable Gate Array (FPGA), or other hardware or software, or a combination of hardware and software.

In addition, it is intended to clarify that the division of the constituent parts in this specification is only classified according to main functions of each constituent part. That is, two or more components to be described below may be combined into one component, or one component may be divided into two or more for each subdivided function. In addition, each of the components to be described below may additionally perform some or all of the functions in charge of other components in addition to the main functions in charge of the components, and some of the main functions in charge of each of the components are different. Needless to say, it may also be carried out in a dedicated manner. Hereinafter, embodiments according to the technical spirit of the present invention will be described in detail.

1 is a diagram schematically showing some components of a mobile communication system according to an embodiment of the present invention.

Referring to Figure 1, the wireless communication system 10 according to an embodiment of the present invention is a base station (BTS, Base Transceiver Station, 110), a mobile communication repeater (Repeater, 120) and a mobile communication terminal (Mobile Terminal, 130) Includes. The base station 110, the mobile communication repeater 120 and the mobile communication terminal 130 may be wirelessly connected to each other.

The base station 110 and the mobile communication repeater 120 may connect the mobile communication network and the mobile communication terminal 130 for mobile communication service. The mobile communication network connected to the base station 110 processes calls and calls from each base station through a connection with each base station controller (BSC), and a central control function that enables all base stations to operate efficiently. Together, it may be operated by a mobile communication switch (not shown) that serves to form a connection with another network, such as a public switched network (PSTN).

The mobile communication repeater 120 may amplify the signal transmitted from the mobile communication terminal 130 and transmit it to the base station 110. In addition, the mobile communication repeater 120 may amplify a signal received from a transmitting side (eg, a transmitter terminal (not shown)) and transmit it to the base station 110. That is, when a smooth signal transmission is difficult because the distance between the base station 110 and the mobile communication terminal 130 is far, the mobile communication repeater 120 may serve as a signal amplification between the base station 110 and the mobile communication terminal 130. .

In addition, the mobile communication repeater 120 according to an embodiment of the present invention may be formed of a module in which internal components are replaceable in order to improve mobile communication network management efficiency. Hereinafter, the configuration and operation of the mobile communication repeater 120 according to the embodiment of the present invention will be described in detail with reference to FIGS. 2 to 5.

2 is a block diagram of the configuration of a mobile communication repeater according to an embodiment of the present invention.

Referring to FIG. 2, the mobile communication repeater 120 according to an embodiment of the present invention includes a case 210, a power module 220, an antenna module 230, and n frequency modules 240-1 to 240-n. ) (Where n is a natural number of 2 or more), and includes a digital processing module 250.

Each module 210 to 250 included in the mobile communication repeater 120 according to an embodiment of the present invention may be accommodated to be detachable from the case 210. Here, the case 210 may be a member having a space therein to accommodate one or more modules 220 to 250. Therefore, the case 110 may occupy most of the volume in the mobile communication repeater 120 and may have a rectangular box shape having a constant volume to accommodate each module 220 to 250 therein. However, the shape of the case 210 is not limited to a rectangular box, and any shape that can accommodate each module 220 to 250 is possible without limitation.

In addition, in FIG. 2, one surface of the case 210 is opened and each module 220 to 250 is exposed to the outside, but the present invention is not limited thereto and all surfaces of the case 210 are blocked or a separate door is opened. It is possible to protect the mobile communication repeater 120 from the outside by implementing so that one surface opened through it can be opened and closed. At this time, if the case 210 is provided with a separate door, the door may be hinged to the case 210, and a separate locking/unlocking portion may be provided to lock the door to the case 110 in a locked state. .

In addition, a terminal 260 corresponding to each module 220 to 250 may be formed inside the case 210, and a terminal connected to the terminal 260 of the case is also provided on the lower surface of each module 220 to 250 ( May be formed). Therefore, each module 220 to 250 may be electrically connected through a preset method when mounted in a case.

For example, the antenna module 230 may include a link antenna (not shown) and a service antenna (not shown), and the link antenna (not shown) is connected to the first frequency module 240-1, and is serviced. The antenna (not shown) may be connected to the n-th frequency module 240-n. In addition, each frequency module (240-1 to 240-n) may be connected to the digital processing module 250. In addition, the power module 220 is connected to the antenna module 230, n frequency modules 240-1 to 240-n and the digital processing module 250, respectively, so that each module 230 to 250 is electrically operated. Can deliver power.

Hereinafter, the operation of each operation module 230 to 250 of the mobile communication repeater 120 will be described in detail with reference to FIGS. 3 to 5.

3 is a block diagram of a logical function of a mobile communication repeater according to an embodiment of the present invention.

3, the antenna module 230, the first frequency module 240-1, the second frequency module 240-2, and the digital processing module 250 are equipped with a mobile communication repeater 120 mounted in the case 210. For example. Although not shown in FIG. 3, it is apparent that the power module 220 is connected to each of the modules 230 to 250 to provide power required for operation.

The antenna module 230 may include a link antenna 310 and a service antenna 380. The link antenna 310 is connected to the first frequency module 240-1 and outputs a signal received from the base station 110 (hereinafter referred to as a “downlink signal”) to the first frequency module 240-1. Can. In addition, the link antenna 310 may transmit a signal input from the first frequency module 240-1 (hereinafter referred to as an'uplink signal') to the base station 110.

In addition, the service antenna 380 is connected to the second frequency module 240-2, and the signal received from the mobile communication terminal 130 (hereinafter referred to as the'uplink signal') is the second frequency module 240-2. Can be output as Also, the service antenna 380 may transmit a signal input from the second frequency module 240-2 to the mobile communication terminal 130.

The first frequency module 240-1 includes a first redundancy unit 320-1, a first link interface unit 330-1, a first service interface unit 380-1, and a first downlink noise removal unit ( 340-1), a first downlink analog processing unit 350-1, a first uplink noise removal unit 360-1, and a first uplink analog processing unit 370-1. In addition, the second frequency module 240-2 includes a second redundancy unit 320-2, a second link interface unit 330-2, a second service interface unit 380-2, and a second downlink noise removal unit. (340-2), a second downlink analog processing unit 350-2, a second uplink noise removal unit 360-2 and a second uplink analog processing unit 370-2.

First, an operation in which the first frequency module 240-1 and the second frequency module 240-2 process the downlink signal input from the link antenna 310 will be described. In this case, it is assumed that the downlink signal is a combined signal of the first frequency downlink signal and the second frequency downlink signal.

The first redundancy unit 320-1 receives a downlink signal input from the link antenna 310 and corresponds to a preset first frequency band (hereinafter referred to as a'first frequency downlink signal') and a preset second. It can be separated into a signal corresponding to the frequency band signal (hereinafter referred to as'second frequency downlink signal'). Here, the first redundancy unit 320-1 may include a diplexer capable of separating bands of two signals having distinct frequency differences without loss of power. Hereinafter, a configuration of the first redundancy unit 320-1 according to an embodiment of the present invention will be described in more detail with reference to FIG. 4.

4 is a block diagram of a first duplexer according to an embodiment of the present invention.

Referring to FIG. 4, the first redundancy unit 320-1 according to an embodiment of the present invention may include a first bandpass filter 410 and a first bandstop filter 420. Therefore, the first redundancy unit 320-1 may separate the first frequency downlink signal through the first band pass filter 410 from the downlink signal input through the link antenna 310, and the second band stop filter. The second frequency downlink signal may be separated through 420.

According to this configuration, if the frequency difference between the first frequency downlink signal and the second frequency downlink signal is clear (that is, 20 or more [db]), the first duplexer 320-1 first frequency downlink signal and second frequency The downlink signal can be separated without loss.

Referring to FIG. 3 again, the first redundancy unit 320-1 may output a first frequency downlink signal to the first link interface unit 330-1. Also, the first duplexer 320-1 may output the second frequency downlink signal to the second link interface unit 330-2, and the second frequency downlink signal is processed by the second frequency module 240-2. This operation will be described later.

The first link interface unit 330-1 may output the first frequency downlink signal to the first downlink noise removal unit 340-1, and the first downlink noise removal unit 340-1 may be input. The first noise canceling downlink signal may be generated by removing the noise of the first frequency downwardsignal. Therefore, the first downlink noise removal unit 340-1 may be formed by including a LNA (Low Noise Amplifier). The first downlink noise removal unit 340-1 may output the first noise removal downlink signal to the digital processing module 250.

The digital processing module 250 may convert the input analog signal to a digital signal, process the digital signal converted through the provided digital filter, and convert the processed digital signal to an analog signal and output the converted digital signal. Accordingly, the digital processing module 250 may include a digital to analog converter (DAC), a digital filter and an analog to digital converter (ACD).

Therefore, the digital processing module 250 converts the input first noise canceling downlink signal into a digital signal through a DAC (not shown), and corresponds to the first noise canceling downlink signal converted into the digital signal in the first frequency band. After processing through a digital filter (not shown), it can be converted back to an analog signal (hereinafter referred to as a'first digital processing down signal') through ACD (not shown). Thereafter, the digital processing module 250 may output the first digital processing downlink signal to the first downlink analog processing unit 350-1.

The first downlink analog processing unit 350-1 may amplify the input first digital processing downlink signal according to a preset gain to generate a first downlink downlink signal. Therefore, the first downlink analog processing unit 350-1 may be formed including a PA (Power Amplifier). The first downlink analog processing unit 350-1 may output the first amplified downlink signal to the first service interface unit 380-1.

The first service interface unit 380-1 may output the input first amplification downlink signal to the second redundancy unit 320-2. The second redundancy unit 320-2 may output the input first amplification downlink signal to the service antenna 380. The service antenna 380 may radiate the first amplified downlink signal to the outside to be transmitted to the receiving mobile communication terminal 130.

Meanwhile, as described above, the first redundancy unit 320-1 may output the second frequency downlink signal to the second link interface unit 330-2. Therefore, the second link interface unit 330-2 may output the input second frequency downlink signal to the second downlink noise removal unit 340-2, and the second downlink noise removal unit 340-2. May remove the noise of the input second frequency down signal to generate a second noise down signal. Therefore, the second downlink noise removal unit 340-2 may be formed by including a low noise amplifier (LNA). The second downlink noise removal unit 340-2 may output the second noise removal downlink signal to the digital processing module 250.

The digital processing module 250 converts the input second noise reduction downward signal into a digital signal through a DAC (not shown), and the second noise reduction downward signal converted into digital signals corresponds to the second frequency band. After processing through a digital filter (not shown), it can be converted back to an analog signal (hereinafter referred to as a'second digital processing down signal') through ACD (not shown). Thereafter, the digital processing module 250 may output the second digital processing downlink signal to the second downlink analog processing unit 350-2.

The second downlink analog processing unit 350-2 may amplify the input second digital processing downlink signal according to a preset gain to generate a second downlink downlink signal. Therefore, the second downlink analog processing unit 350-2 may be formed by including a power amplifier (PA). The second downlink analog processing unit 350-2 may output the second amplified downlink signal to the second service interface unit 380-2.

The second service interface unit 380-2 may output the input second amplification downlink signal to the second redundancy section 320-2, and the second redundancy section 320-2 may output the second amplification downlink signal. It can be output to the service antenna 380. The service antenna 380 may radiate the second amplified downlink signal to the outside and transmit it to the receiving mobile communication terminal 130. At this time, the second redundancy unit 320-2 may combine the input first amplification downlink signal and the second amplification downlink signal and output it to the service antenna 380.

Hereinafter, an operation in which the first frequency module 240-1 and the second frequency module 240-2 process the uplink signal input from the service antenna 380 will be described. In this case, it is assumed that the uplink signal is a signal in which the first frequency downlink signal and the second frequency downlink signal are combined.

The second redundancy unit 320-2 receives the uplink signal input from the service antenna 380 corresponding to a preset first frequency band (hereinafter referred to as a'first frequency uplink signal') and a preset second It can be separated into a signal corresponding to the frequency band signal (hereinafter referred to as'second frequency up signal'). Here, the second redundancy unit 320-2 may include a diplexer capable of separating bands of two signals having distinct frequency differences without loss of power, and the configuration thereof is described with reference to FIG. 4. 1 It may be the same or similar to the configuration of the redundancy unit 320-1.

The second redundancy unit 320-2 may output the second frequency enhancement signal to the second service interface unit 330-2. In addition, the second redundancy unit 320-2 may output the first frequency enhancement signal to the first service interface unit 380-1, and the first frequency enhancement signal is processed by the first frequency module 240-1. This operation will be described later.

The second service interface unit 380-2 may output the second frequency uplink signal to the second uplink noise removal unit 360-2, and the second uplink noise removal unit 360-2 may input the The second noise cancellation up signal may be generated by removing the noise of the second frequency up signal. Therefore, the second uplink noise removal unit 360-2 may be formed by including a LNA (Low Noise Amplifier). The second uplink noise removal unit 360-2 may output the second noise removal uplink signal to the digital processing module 250.

The digital processing module 250 converts the input second noise canceling up signal into a digital signal through a DAC (not shown), and converts the second noise canceling up signal converted into digital signals into a second frequency band. After processing through a digital filter (not shown), it can be converted back to an analog signal (hereinafter referred to as a'second digital processing up signal') through ACD (not shown). Thereafter, the digital processing module 250 may output the second digital processing uplink signal to the second uplink analog processing unit 370-2.

The second uplink analog processing unit 370-2 may amplify the input second digital processing enhancement signal according to a preset gain to generate a second amplification enhancement signal. Therefore, the second uplink analog processing unit 370-2 may be formed by including a power amplifier (PA). The second uplink analog processing unit 370-2 may output a second amplified uplink signal to the second link interface unit 330-2.

The second link interface unit 330-2 may output the input second amplification enhancement signal to the first redundancy unit 320-1. The first duplexer 320-1 may output the input second amplification up signal to the link antenna 310. The link antenna 310 may radiate the second amplified boost signal to the outside so that the second amplified boost signal is transmitted to the base station 110.

Meanwhile, as described above, the second redundancy unit 320-2 may output the first frequency uplink signal to the first service interface unit 380-1. Accordingly, the first service interface unit 380-1 may output the input first frequency uplink signal to the first uplink noise removal unit 360-1, and the first uplink noise removal unit 360-1. May remove the noise of the input first frequency up signal to generate a first noise up signal. Therefore, the first uplink noise removal unit 360-1 may be formed by including a LNA (Low Noise Amplifier). The first uplink noise removal unit 360-1 may output the first noise removal uplink signal to the digital processing module 250.

The digital processing module 250 converts the input first noise canceling upward signal into a digital signal through a DAC (not shown), and converts the first noise canceling upward signal converted into a digital signal into a first frequency band. After processing through a digital filter (not shown), it can be converted back to an analog signal (hereinafter referred to as a'first digital processing up signal') through ACD (not shown). Thereafter, the digital processing module 250 may output the first digital processing uplink signal to the first uplink analog processing unit 370-1.

The first uplink analog processing unit 370-1 may amplify the input first digital processing uplink signal according to a preset gain to generate a first amplified uplink signal. Therefore, the first uplink analog processing unit 370-1 may be formed by including a power amplifier (PA). The first uplink analog processing unit 370-1 may output the first amplified uplink signal to the first link interface unit 330-1.

The first link interface unit 330-1 may output the input first amplification enhancement signal to the first redundancy unit 320-1, and the first redundancy unit 320-1 may input the first amplification enhancement signal. The signal may be output to the link antenna 310. The link antenna 310 may radiate the first amplification boost signal to the outside so that the first amplification boost signal is transmitted to the base station 110. In this case, the first redundancy unit 320-1 may combine the input first amplification uplink signal and the second amplification uplink signal and output the link to the link antenna 310.

In the above, the case where the first frequency module 240-1 and the second frequency module 240-2 are mounted on the mobile communication repeater 120 according to an embodiment of the present invention has been described. Hereinafter, a case in which n frequency modules 240-1 to 240-n are mounted on the mobile communication repeater 120 according to an embodiment of the present invention will be described with reference to FIG. 5.

5 is a block diagram of a logical function of a mobile communication repeater according to another embodiment of the present invention.

In FIG. 5, the antenna module 230, the first frequency module 240-1 to the n-th frequency module 240-n and the digital processing module 250 are equipped with a mobile communication repeater 120 mounted in the case 210. For example. Although not shown in FIG. 5, it is apparent that the power module 220 is connected to each of the modules 230 to 250 to provide power required for operation. In addition, although not shown in FIG. 5, the mobile communication repeater 120 may be equipped with n frequency modules 240-1 to 240-n, such that the n-1 frequency module (not shown) and the n-2 The frequency module may also be connected to the power module 220 to receive power required for operation. Hereinafter, a signal processing operation in the case where n repeater modules 240-1 to 240-n are connected to the mobile communication repeater 120 according to another embodiment of the present invention will be described in detail.

The antenna module 230 may include a link antenna 310 and a service antenna 380. The link antenna 310 is connected to the first frequency module 240-1 and outputs a signal received from the base station 110 (hereinafter referred to as a “downlink signal”) to the first frequency module 240-1. Can. In addition, the link antenna 310 may transmit a signal input from the first frequency module 240-1 (hereinafter referred to as an'uplink signal') to the base station 110.

In addition, the service antenna 380 is connected to the nth frequency module 240-n and receives a signal received from the mobile communication terminal 130 (hereinafter referred to as an'uplink signal') to the nth frequency module 240-2. Can be output as Also, the service antenna 380 may transmit a signal input from the nth frequency module 240-n to the mobile communication terminal 130.

Therefore, the second frequency module (not shown) to the n-1 frequency module (not shown) may not be connected to the antenna module 230.

First, an operation in which the first frequency module 240-1 to the nth frequency module 240-n processes the downlink signal input from the link antenna 310 will be described. In this case, it is assumed that the downlink signal is a signal in which two or more of the first frequency downlink signal to the nth frequency downlink signal are combined.

The first frequency module 240-1 includes a first multiplexing unit 520-1, a first link interface unit 330-1, a first service interface unit 380-1, and a first downlink noise removal unit ( 340-1), a first downlink analog processing unit 350-1, a first uplink noise removal unit 360-1, and a first uplink analog processing unit 370-1. Also, the nth frequency module 240-n includes an nth multiplexer 520-n, an nth link interface unit 330-n, an nth service interface unit 380-n, and an nth downlink noise removing unit. (340-n), n-th downlink analog processing unit (350-n), n-th uplink noise removal unit (360-n) and n-th uplink analog processing unit (370-n).

Similarly, although not shown, the n-1 frequency module (not shown) includes an n-1 multiplexer (not shown), an n-1 link interface unit (not shown), and an n-1 service interface unit (not shown). ), n-1 downlink noise removing unit (not shown), n-1 downlink analog processing unit (not shown), n-1 uplink noise removing unit (not shown) and n-1 uplink analog It may include a processing unit (not shown).

First, the first multiplexer 520-1 is a frequency band different from a signal corresponding to a preset first frequency band (hereinafter referred to as a'first frequency downlink signal') from a downlink signal input from the link antenna 310. It can be separated into a signal corresponding to (hereinafter referred to as'first other frequency down signal'). Here, the first multiplexer 520-1 may include a diplexer capable of separating the bands of two signals having a clear frequency difference without loss of power, the configuration of which is described with reference to FIG. 4. 1 It may be the same or similar to the configuration of the redundancy unit 320-1.

Also, the first multiplexer 520-1 may output the first frequency downlink signal to the first link interface unit 330-1. Since the first frequency module 240-1 processes the first frequency downlink signal and outputs the first amplified downlink signal is the same or similar to that described with reference to FIG. 3, detailed description thereof will be omitted. However, the first link interface unit 330-1 may output the first amplification downlink signal to the first multiplexer 520-1, and the first multiplexer 520-1 may output the first amplification downlink signal. It can be output to the n-th multiplexing unit (520-n).

Also, the first multiplexer 520-1 may output a first other frequency downlink signal to a second frequency module (not shown). That is, the second multiplexing unit (not shown) included in the second frequency module (not shown) separates the first other frequency downlink signal into the second frequency downlink signal and the second other frequency downlink signal through the provided diplexer. can do. Thereafter, the second frequency module (not shown) may process the second frequency downlink signal to generate a second amplified downlink signal, and the second multiplexer (not shown) may transmit the second amplified downlink signal to the nth multiplexer 520. -n). In addition, the second multiplexer (not shown) may output the second other frequency downlink signal to the third frequency module (not shown).

According to the same or similar method, the n-1 multiplexer (not shown) included in the n-1 frequency module (not shown) transmits the n-2 second frequency downlink signal through the provided diplexer to the n-1 It can be divided into a frequency downlink signal and an n-1 other frequency downlink signal. Thereafter, the n-1 frequency module (not shown) may process the n-1 frequency downlink signal to generate an n-1 amplified downlink signal, and the n-1 multiplexer (not shown) may transmit the n-1 frequency downlink signal. The amplified downlink signal may be output to the nth multiplexer 520-n. Also, the n-1 multiplexer (not shown) may output the n-1 other frequency downlink signal to the nth frequency module 240-n.

Also, the n-th multiplexer 520-n may output the n-th frequency down signal included in the n-1 other frequency down signal to the n-th link interface unit 330-n. Thereafter, the operation of the n-th frequency module 240-n processing the n-th frequency downlink signal and outputting the n-th amplification downlink signal is the same or similar to that described with reference to FIG. 3, and thus detailed description thereof is omitted. However, the first multiplexer 520-1 may combine the input first amplification downlink signal to the nth amplification downlink signal and output the result to the service antenna 380.

Hereinafter, an operation in which the first frequency module 240-1 to the nth frequency module 240-n processes the uplink signal input from the service antenna 380 will be described. In this case, it is assumed that the uplink signal is a signal in which the first to nth frequency downlink signals are combined.

First, the n-th multiplexer 520-n uses a frequency band different from a signal corresponding to a preset n-th frequency band (hereinafter referred to as an'n-th frequency up signal') from an uplink signal input from the service antenna 380. It can be separated into a signal corresponding to (hereinafter referred to as'n-th other frequency upward signal'). Here, the n-th multiplexer 520-n may include a diplexer capable of separating bands of two signals having a clear frequency difference without loss of power, and the configuration is described with reference to FIG. 4. 1 It may be the same or similar to the configuration of the redundancy unit 320-1.

Also, the n-th multiplexing unit 520-n may output the n-th frequency uplink signal to the n-th service interface unit 330-n. Subsequently, the operation of the n-th frequency module 240-n processing the n-th frequency up signal and outputting the n-th amplified up signal is the same or similar to that described with reference to FIG. 3, and thus detailed description thereof will be omitted. However, the n-th service interface unit 330-n may output the n-th amplification up signal to the n-th multiplexer 520-n, and the n-th multiplexer 520-n may output the n-th amplification up signal. It can be output to the first multiplexer 520-1.

Also, the n-th multiplexer 520-n may output an n-th other frequency up signal to an n-1 frequency module (not shown). That is, the n-1 multiplexer (not shown) included in the n-1 frequency module (not shown) transmits the n th other frequency up signal to the n-1 frequency up signal and n th through the provided diplexer. -1 Can be separated into other frequency up signal. Thereafter, the n-1 frequency module (not shown) may process the n-1 frequency up signal to generate an n-1 amplified up signal, and the n-1 multiplexer (not shown) may use the n-1 The amplified uplink signal may be output to the first multiplexer 520-1. Also, the n-1 multiplexer (not shown) may output the n-1 other frequency uplink signal to the n-2 frequency module (not shown).

According to the same or similar method, the second multiplexing unit (not shown) included in the second frequency module (not shown) transmits the third other frequency up signal to the second frequency up signal and the second other frequency through the provided diplexer. It can be separated by an upward signal. Thereafter, the second frequency module (not shown) may process the second frequency up signal to generate a second amplified up signal, and the second multiplexer (not shown) may transmit the second amplified up signal to the first multiplexer 520. -1). In addition, the second multiplexer (not shown) may output the second other frequency upward signal to the first frequency module 240-1.

Also, the first multiplexer 520-1 may output the first frequency up signal included in the second other frequency up signal to the first service interface unit 330-1. Since the first frequency module 240-1 processes the first frequency up signal and outputs the first amplified up signal is the same or similar to that described with reference to FIG. 3, detailed description thereof will be omitted. However, the first multiplexer 520-1 may combine the input first amplification up signal to the nth amplification up signal to output the link antenna 310.

As described above, the mobile communication repeater 120 according to an embodiment of the present invention is formed so that each of the configured modules, particularly a plurality of frequency modules 240-1 to 240-n, can be detached, so that even if the service frequency is changed, the mobile communication The repeater 120 itself may not be replaced. In addition, the digital processing module 250 may not be replaced as long as the digital filter provided to correspond to the changed frequency module can be modified by the administrator when any frequency module is changed.

Accordingly, according to the present invention, it is possible to provide a mobile communication repeater that can improve the efficiency of mobile communication network management through a replaceable communication module and facilitate the operation of replacing internal parts.

As described above, the technical idea of the present invention has been described in detail with reference to preferred embodiments, but the technical idea of the present invention is not limited to the above embodiments, and those having ordinary knowledge in the art within the scope of the technical idea of the present invention. Various modifications and changes are possible.

110: base station
120: mobile communication repeater
130: mobile communication terminal
210: case
220: power module
230: antenna module
240-n: nth frequency module
250: digital processing module

Claims (15)

delete delete delete delete delete case;
It is accommodated so as to be detachably attached to the case, is connected to the link antenna, separates the first frequency downlink signal and the second frequency downlink signal from the downlink signal input from the link antenna, and removes the noise of the first frequency downlink signal. A first frequency module for outputting a first noise canceling downlink signal, outputting a first amplification downlink signal amplifying the first digital processing downlink signal, and outputting the second frequency downlink signal;
A second amplified downlink signal that is accommodated so as to be detachably attached to the case, is connected to a service antenna, outputs a second noise downlink signal from which noise of the second frequency downlink signal is removed, and amplifies the second digital processing downlink signal. A second frequency module outputting the signal to the service antenna and outputting the first amplified downlink signal to the service antenna; And
The first digital processing downlink signal, which is accommodated so as to be detachably attached to the case, is digitally converted, digitally processed and analogly converted from the first noise reduction downlink signal input from the first frequency module, is output to the first frequency module. A digital processing module for digitally converting, digitally and analogly converting the second noise canceling down signal input from the second frequency module to the second frequency module;
Including,
The second frequency module,
The first frequency up signal and the second frequency up signal are separated from the uplink signal inputted from the service antenna, and a second noise canceling up signal is obtained by removing noise of the second frequency up signal, and the second digital processing up. Outputting a second amplified uplink signal that amplifies the signal to the first frequency module, and outputting the first uplink signal to the first frequency module,
The first frequency module,
Outputs a first noise canceling enhancement signal from which noise of the first frequency enhancement signal is removed, outputs a first amplification enhancement signal obtained by power-amplifying the first digital processing enhancement signal to the link antenna, and outputs the second amplification enhancement signal. Output to the link antenna,
The digital processing module,
The first digital processing enhancement signal, which is digitally converted, digitally processed, and analog-converted the first noise removal enhancement signal input from the first frequency module, is output to the first frequency module, and input from the second frequency module. Digitally converting the second noise canceling up signal, digital processing and analog converting the second digital processing up signal to output to the second frequency module,
Mobile communication repeater, characterized in that.
The method of claim 6,
The second frequency module,
A second duplexing unit connected to the service antenna, separating the first frequency up signal and the second frequency up signal from the uplink signal, and outputting the first frequency up signal to the first frequency module;
Mobile communication repeater comprising a.
The method of claim 7,
The first frequency module,
A first service interface unit connected to the second redundancy unit and receiving the first frequency enhancement signal;
Mobile communication repeater comprising a.
The method of claim 6,
The first frequency module,
A first duplexing unit connected to the link antenna, connected to the second frequency module, and outputting the second amplified upward signal input from the second frequency module to the link antenna;
Mobile communication repeater comprising a.
The method of claim 9,
The second frequency module,
A second link interface unit connected to the first redundancy unit and outputting the second amplified upward signal;
Mobile communication repeater comprising a.
delete The method of claim 7,
The second duplexing unit,
A diplexer separating the first frequency uplink signal and the second frequency uplink signal from the uplink signal;
Mobile communication repeater comprising a.
case;
It is accommodated detachably in the case, is connected to the link antenna, separates a first frequency downlink signal and a first other frequency downlink signal from a downlink signal input from the link antenna, and reduces the noise of the first frequency downlink signal. A first frequency module for outputting the removed first noise-removing downlink signal, outputting a first amplification downlink signal amplifying the first digital processing downlink signal, and outputting the first other frequency downlink signal;
It is accommodated so as to be detachably attached to the case, and separates the n-1 frequency down signal and the n-1 other frequency down signal included in the first other frequency down signal, and reduces the noise of the n-1 frequency down signal. An n-th outputting the removed n-1 noise downlink signal, outputting an n-1 amplified downlink signal amplifying the n-1 digital processing downlink signal, and outputting the n-1 other frequency downlink signal -1 frequency module- provided that n is a natural number of 3 or more;
It is accommodated so as to be detachably attached to the case, is connected to a service antenna, and outputs an n-th noise rejection down signal that removes noise of the n-th frequency down signal included in the n-1 other frequency down signal, and performs nth digital processing. An n-th frequency module for outputting an n-amplification downlink signal amplifying a downlink signal to the service antenna, and outputting the first amplification downlink signal and the n-1 amplification downlink signal to the service antenna; And
The first digital processing downlink signal, which is accommodated so as to be detachably attached to the case, is digitally converted, digitally processed and analogly converted from the first noise reduction downlink signal input from the first frequency module, is output to the first frequency module. , Digitally converting, converting, and digitally converting the n-1 noise canceling downlink signal input from the n-1 frequency module to the n-1 frequency module and outputting the n-1 digital processing downlink signal. A digital processing module for digitally converting, digitally and analogly converting the n-th noise removing downlink signal input from the n-th frequency module to the n-th frequency module;
Mobile communication repeater comprising a.
The method of claim 13,
It is accommodated so as to be detachably attached to the case, and separates the n-2 frequency down signal and the n-2 second frequency down signal included in the first other frequency down signal, and reduces the noise of the n-2 frequency down signal. Outputs the removed n-2 noise removal downlink signal, outputs an n-2 amplified downlink signal amplifying the n-2 digital processing downlink signal to the nth frequency module, and the n-2 second frequency downlink An n-2 frequency module that outputs a signal to the n-1 frequency module, provided that n is a natural number of 4 or more;
Including more,
The digital processing module digitally converts, digitally and analogly converts the n-2 noise reduction downlink signal input from the n-2 frequency module to the n-2 frequency of the n-2 digital processing downlink signal. Output to the module,
The n-1 frequency module separates the n-2 second frequency down signal into the n-1 frequency down signal and the n-1 other frequency down signal,
The n-th frequency module is a mobile communication repeater, characterized in that for outputting the n-2 amplified downlink signal to the service antenna.
The method of claim 13,
The nth frequency module,
The n-th frequency up signal and the n-th other frequency up signal are separated from the uplink signal inputted from the service antenna, and the n-th noise canceling up signal from which the noise of the n-th frequency up signal is removed is output, and the n-th digital processing The n-th amplification up signal that amplifies the uplink signal is output to the first frequency module, and the n-th other frequency up signal is output to the n-1 frequency module,
The n-1 frequency module,
The n-1 frequency up signal and the n-1 other frequency up signal are separated from the nth other frequency up signal, and an n-1 noise canceling up signal is output by removing noise of the n-1 up frequency signal. And outputs an n-1 amplified up signal that amplifies the n-1 digital processing up signal to the first frequency module, and outputs the n-1 other frequency up signal,
The first frequency module,
Outputs a first noise canceling enhancement signal that removes noise of a first frequency enhancement included in the n-1 frequency enhancement signal, and outputs a first amplification enhancement signal that power-amplifies the first digital processing enhancement signal to the link antenna. And outputs the nth amplification up signal and the n-1 amplification up signal to the link antenna,
The digital processing module,
Digitally converting, digitally and analogly converting the first noise canceling enhancement signal input from the first frequency module to output the first digital processing enhancement signal to the first frequency module, and from the n-1 frequency module. The n-1 digital processing enhancement signal, which has been digitally converted, digitally processed, and analog-converted the input n-1 noise removal enhancement signal is output to the n-1 frequency module, and is input from the nth frequency module. And outputting the nth digital processing enhancement signal, which is digitally converted, digitally processed, and analog-converted the nth noise removal enhancement signal to the nth frequency module.

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